KR100896510B1 - Microorganism media for disposal of sewage and waste water - Google Patents

Abstract

The present invention relates to a microbial media for wastewater treatment, and more particularly, in a microbial media that microorganisms are adsorbed and activated, a spherical body having an empty inside and penetrating both sides to form an inlet and an outlet, and the body inner surface It consists of a plurality of partitions fixed to the partition partitioning the internal space, and the adsorption ribs provided in a shape protruding on the surface of the partition to increase the surface area where the microorganisms are adsorbed, the waste water introduced into the inlet stays inside the body It is characterized in that it is decomposed by the effluent and flows out to the outlet, whereby the adsorption surface area that the microorganisms can proliferate is wide, so that the microbial propagation is easy and the retention time of waste water is extended, so that the adsorption of contaminants occurs, so that the decomposition of the pollutants Not only is it efficient, but it is also By using a plurality of the year it can be made larger and the miniaturization of free wastewater treatment facilities.

Microorganisms, Media, Adsorption, Bulkheads, Ribs, Inlets, Outlets, Wastewater

Description

MICROORGANISM MEDIA FOR DISPOSAL OF SEWAGE AND WASTE WATER}

The present invention relates to a microbial media, to a microbial media for wastewater treatment to form a space in which microorganisms can be internally disposed to treat the wastewater, and the microorganisms decompose contaminants while the wastewater remains in the space.

There are many methods that use microorganisms to biologically purify wastewater collected from livestock facilities, factories, and households, or river water with severe water pollution.

This is carried out by submerging the media (media) or carrier, which means a shape or material that can be inhabited by microorganisms into waste water or rivers, and the media is conventionally used for gravel, waste tires, crushed stone, waste wood, etc. The fibrous materials were used using the existing shapes or considering plastic foams and specific surface areas.

However, the gravel, waste tires, and the like has a disadvantage in that the size of the purification device is increased to increase the filling amount of the media because the porosity to which microorganisms can be attached.

Therefore, recently, various shapes of plastic media have emerged. In the case of such plastic media, microorganisms are difficult to adsorb and multiply, and the waste water has a small area of contact with the microorganisms in the media and lacks the residence time, which leads to smooth decomposition of contaminants. There is a disadvantage that does not occur.

The present invention has been made to solve the above problems, an object of the present invention is to ensure sufficient surface area and space for the microorganisms to adsorb and proliferate in the microbial media, the retention time of the waste water is extended, contaminants are well Adsorption is to provide a microbial media for wastewater treatment, by which the wastewater is decomposed by microorganisms and the treatment efficiency is improved.

In order to achieve the above object, the present invention provides a microbial medium for adsorbing and activating microorganisms, and having a spherical body having an empty inside and penetrating both sides to form an inlet and an outlet, and fixed to an inner surface of the body. Comprising a plurality of partitions partitioning the space and the adsorption ribs provided in a shape protruding on the surface of the partition to increase the surface area where the microorganisms are adsorbed, the waste water flowing into the inlet is decomposed by the microorganisms while remaining inside the body and the Characterized in that the outflow to the outlet.

Preferably, the body is composed of an upper hemisphere and a lower hemisphere, and the partition wall is characterized in that it is divided into an upper partition formed in the upper hemisphere and a lower partition formed in the lower hemisphere while having a fan shape.

Preferably, the upper partition and the lower partition is characterized in that arranged alternately with each other.

Preferably, one side of each partition wall is disposed on an extension line connecting the inlet and the outlet to form a flow path, characterized in that the flow path has a shape that narrows to one side.

Preferably, the adsorption rib has an elongated plate shape and is inclinedly coupled to both sides of the partition wall, and is disposed to be inclined opposite to the partition walls adjacent to each other.

Preferably, the adsorption ribs are formed in a rod shape and is formed perpendicular to both sides of the partition wall.

The effect of the present invention by the above-described configuration is excellent in the decomposition efficiency of contaminants because the adsorption surface area that microorganisms can proliferate is easy to grow microorganisms and the residence time of waste water is prolonged, so that adsorption of contaminants occurs well.

In addition, since the media can be miniaturized, it is possible to freely increase and reduce the size of the wastewater purification facility by using a plurality of media.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the present invention will be described in detail.

1 is a perspective view showing a microbial media for wastewater treatment according to an embodiment of the present invention, Figure 2 shows an exploded perspective view of the present invention shown in Figure 1, Figure 2 (a) is the upper hemisphere and the upper partition, Figure 2 (b) shows the lower hemisphere and the lower bulkhead.

The present invention is largely composed of the body 10, the partition wall 20, the suction rib (30).

As shown in FIG. 1, in the present invention, a plurality of partition walls 20 are coupled to an inner surface of the body 10 and a suction rib having a shape protruding on a surface of each partition wall 20. 30 is formed in a plurality, the microorganisms are attached to the surface of the partition wall 20 and the adsorption ribs 30 is a structure that can proliferate.

First, the body 10 will be described.

The body 10 has a spherical shape with an empty inside and penetrates through a pole to form an inlet 12 and an outlet 14, respectively.

In addition, the body 10 is composed of a hemispherical upper hemisphere 16 and the lower hemisphere 18 and the material may be made of a variety of metals, wood, synthetic resins, polymer compounds, etc., but synthetic resins are preferred.

The synthetic resin is advantageous because it is easy to manufacture by molding and is light and strong against water and contaminants.

In addition, since the molding is possible by mixing various additives in the synthetic resin, various functional effects by the additive can be achieved.

For reference, zeolite, activated carbon, ilite, and the like may be used as the additive. The zeolite functions to separate ammonia from wastewater by replacing ammonia by an ionization reaction, and the activated carbon may have adsorptivity of microorganisms. To increase the porosity and promote the growth of microorganisms by increasing porosity.

Next, the partition wall 20 will be described.

The partition wall 20 has a fan shape and is disposed at regular intervals in the upper hemisphere 16 and the lower hemisphere 18, respectively, and the partition wall 20 disposed in the upper hemisphere 16 has an upper partition wall 22. When the partition wall 20 disposed in the lower hemisphere 18 is referred to as the lower partition wall 24, the upper partition wall 22 and the lower partition wall 24 are alternately disposed without being connected to each other.

In more detail with reference to the bar shown in Figure 1, the lower partition 24 is located between each of the upper partition 22 disposed in the upper hemisphere (16).

Here, one side of the partition wall 20 is in contact with the imaginary extension surface connecting the inlet 12 and the outlet 14, the inlet 12 is larger than the outlet 14 is connected between the two The extended surface to form a tapered shape. Therefore, one side of the partition wall 20 has an inclined shape, respectively.

One side of the partition wall 20 is inclined to form an open virtual flow path 100 that extends from the inlet 12 to the outlet 14, and the flow path 100 is an outlet 14 from the inlet 12. It has a shape that narrows toward).

Since the flow path 100 is narrowed as described above, the time for the wastewater flowing into the inlet 12 to stay inside the body 10 becomes long, and when the oil flows out again through the outlet 14, the outflow speed is increased.

As described above, the material of the partition wall 20 is preferably a synthetic resin, and may add various additives to increase adsorption and proliferation of microorganisms.

Next, the adsorption rib 30 will be described with reference to FIG. 3. 3 is a cross-sectional view taken along the line AA ′ of the present invention shown in FIG. 1.

The adsorption rib 30 is formed on the surface of the partition wall 20 and functions to widen the surface area inside the body 10 so that the microorganisms are attached and proliferate.

Preferably, the adsorption rib 30 has a long flat plate shape and is installed so as to protrude on the surface of the partition wall 20, but it is preferably inclined to one side.

Because the space in the body 10 is narrow, if possible, it is more efficient to make the most of the space to be inclined to one side than the partition is formed vertically.

In addition, although the suction ribs 30 are formed to be inclined, the suction ribs 30 formed on the adjacent partition walls 20 and the inclined directions are more preferably opposite to each other, as shown in FIG. 3. While the suction ribs 30 formed at 20 are inclined toward the center of the body 10, the suction ribs 30 formed at the partition walls 20 adjacent to both sides of the partition wall 20 are formed in the body 10. It is formed to be inclined toward the outside.

This is because when the wastewater introduced through the inlet 12 flows between the adsorption ribs 30, the adsorption ribs 30 are inclined to shift each other so that the flow of the wastewater is interrupted and stays in the body 10. The time to do it will increase more.

Such a structure causes the upper partition 22 and the lower partition 24 to be alternately arranged with each other, thereby increasing the residence time of the wastewater introduced into the body 10.

Therefore, since the wastewater stays in the body for a long time, contaminants contained in the wastewater are adsorbed to the partition walls and the adsorption ribs well, thereby causing active decomposition by microorganisms.

On the other hand, the suction rib 30 is also made of the same material as the body 10 or the partition wall (20).

4 is an exemplary view showing various embodiments of the adsorption rib in the configuration of the present invention.

The adsorption rib 30 may be formed to be bent along an arc of the partition wall 20 as shown in FIG. 4 (a) and may be gathered in one place, and as shown in FIG. 4 (b). Likewise it may be formed in a straight line parallel to each other.

In addition, unlike the above-described flat plate shape, as shown in FIG. 4C, the suction rib 30 may have a rod shape and may be perpendicular to the surface of the partition wall 20.

Since these various shapes all serve to widen the surface area to which microorganisms can be adsorbed and to increase the contact area with the waste water remaining in the body 10, it can have many shapes other than the embodiments described herein. It is predictable.

In addition, the present invention may be manufactured by molding the upper hemisphere 16 and the lower hemisphere 18 separately and bonding to each other, or may be molded into an integral mold.

Hereinafter will be briefly mentioned the operation of the present invention.

The microorganism media for treating wastewater of the ball type corresponding to the present invention is used by inserting a cradle (not shown) filled with a large number into a purification facility.

Waste water enters from one side of the cradle and passes through each microbial media filled in the cradle, thereby purifying purified water.

The wastewater introduced into the inlet 12 of the body 10 is in contact with the microorganisms that propagate on the surface of the partition 20 and the adsorption ribs 30 while staying in the body 10 for a considerable time and thus included in the wastewater. Contaminants stick to the microorganisms and cause degradation.

Purified water is discharged to the outlet 14 by pressure, and the purified water is discharged from the holder and collected in the sump where the purified water is collected and finally purified through an additional process.

Since the present invention described above is only one embodiment, the true scope of the present invention should be determined by the claims that follow.

1 is a perspective view showing a microbial media for wastewater treatment according to an embodiment of the present invention.

2 is an exploded perspective view of the present invention shown in FIG.

3 is a cross-sectional view taken along the AA 'of the present invention shown in FIG.
Figure 4 is an exemplary view showing various embodiments of the adsorption rib in the configuration of the present invention.

<< Explanation of symbols for main part of drawing >>

10 body 12 inlet

14 outlet 16 upper hemisphere

18: lower hemisphere 20: bulkhead

22: upper partition 24: lower partition

30: adsorption rib 100: flow path

Claims (6)

In microbial media that microorganisms are adsorbed and activated, A spherical body 10 which is empty and penetrates both sides to form an inlet 12 and an outlet 14; A plurality of partition walls 20 fixed to an inner surface of the body 10 to define an inner space; Adsorption ribs 30 are formed in a protruding shape on the partition wall 20 so that the surface area to which the microorganism is adsorbed; Wastewater treatment microbial media, characterized in that the wastewater introduced into the inlet 12 is decomposed by the microorganisms while remaining in the body (10) and is discharged to the outlet (14). The method of claim 1, The body 10 is composed of an upper hemisphere 16 and a lower hemisphere 18, The partition wall 20 has a fan shape and is divided into an upper partition 22 formed in the upper hemisphere 16 and a lower partition wall 24 formed in the lower hemisphere 18. Microbial media. The method of claim 2, The upper partition (22) and the lower partition (24) is a microbial media for wastewater treatment, characterized in that the alternating arrangement. The method of claim 3, wherein One side of each of the partition walls 20 is disposed on an extension line connecting the inlet 12 and the outlet 14 to form a flow path 100, the flow path 100 has a shape that narrows to one side Microbial media for wastewater treatment. The method according to any one of claims 1 to 4, The adsorption rib 30 has an elongated plate shape and is inclinedly coupled to both sides of the partition wall 20, and disposed to be inclined opposite to the partition wall 20 adjacent to each other. The method according to any one of claims 1 to 4, The adsorption rib 30 has a rod shape and is formed on both sides of the partition wall 20, the microbial media for wastewater treatment.

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